A method for controlling a wind farm including a plurality of wind turbines is provided. The method includes computing an error between a farm-level base point power and a measured wind farm power, generating an aggregated farm-level active power set point for the wind farm based on the error and a frequency response set point, generating aggregated turbine-level active power set points based on the aggregated farm-level active power set point, transmitting the aggregated turbine-level active power set points, determining aero power set points and storage power set points for the respective wind turbines and energy storage elements of the respective wind turbines from the aggregated turbine-level active power set points, and controlling the plurality of wind turbines for delivering aero power based on the respective aero power set points and controlling the energy storage elements to provide storage power based on the respective storage power set points.
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1. A method for controlling a wind farm comprising a plurality of wind turbines, the method comprising:
computing an error between a farm-level base point power forecast and a measured farm-level active power;
generating an aggregated farm-level active power set point for the wind farm based on the error and a frequency response set point;
generating aggregated turbine-level active power set points for the plurality of wind turbines based on the aggregated farm-level active power set point;
transmitting the aggregated turbine-level active power set points to the respective wind turbines;
using the aggregated turbine-level active power set points for determining aero power set points and storage power set points for the plurality of wind turbines and energy storage elements coupled to the plurality of wind turbines respectively; and
using the aero power set points for controlling the respective wind turbines and the storage power set points for controlling the respective energy storage elements.
11. A system for controlling a wind farm including a plurality of wind turbines, the system comprising:
a wind farm controller for:
computing an error between a farm-level base point power forecast and a measured farm-level active power;
generating an aggregated farm-level active power set point for the wind farm based on the error and a frequency response set point;
generating aggregated turbine-level active power set points for the plurality of wind turbines based on the aggregated farm-level active power set point;
transmitting the aggregated turbine-level active power set points to the respective wind turbines;
wind turbine controllers for:
receiving the aggregated turbine-level active power set points;
using the aggregated turbine-level active power set points for determining aero power set points for the respective wind turbines and storage power set points for energy storage elements coupled to the respective wind turbines; and
using the aero power set points for controlling the respective wind turbines and the storage power set points for controlling the energy storage elements coupled to the respective wind turbines.
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Embodiments of the present invention generally relate to wind turbines and more particularly relate to a system and method for controlling wind turbines in wind farms.
Wind turbines are used to generate electrical power from wind energy. Multiple wind turbines may be coupled together to form a wind farm, and multiple wind farms may be coupled to a power grid. The wind farms are required to provide a committed output power to the power grid. However, due to constant fluctuations in wind speed and in load coupled to the power grid, a difference may occur between the power provided by the wind farm to the power grid and the committed output power. The difference leads to variations in a frequency at the power grid and may require additional wind farm resources for frequency regulation.
In order to overcome the variations in the frequency, wind farms use various frequency response techniques. One type of primary frequency response method includes operating wind turbines in respective wind farms in a curtailed mode during normal operational modes and operating the same wind turbines to provide additional power when frequency decreases or curtail the wind turbines further when frequency increases. However, operating the wind turbines in a curtailed mode during normal operational modes results in revenue losses.
In some situations, the above type of primary frequency response technique is insufficient to maintain a precise control of the frequency in the power grid and a second frequency response technique is employed to precisely control the frequency in the power grid. One example of a secondary frequency response is an automatic generation control embodiment including a centralized wind farm battery that provides additional power to the power grid to maintain the frequency. Such secondary systems lead to additional costs of the wind farm.
It would be desirable for wind farms to have an improved and more cost effective system and method to address frequency variations.
In one embodiment, a method for controlling a wind farm including a plurality of wind turbines is provided. The method includes computing an error between a farm-level base point power forecast and a measured farm-level active power, generating an aggregated farm-level active power set point for the wind farm based on the error and a frequency response set point, generating aggregated turbine-level active power set points for the plurality of wind turbines based on the aggregated farm-level active power set point; transmitting the aggregated turbine-level active power set points to the respective wind turbines, using the aggregated turbine-level active power set points for determining aero power set points for each of the plurality of wind turbines and storage power set points for energy storage elements coupled to each of the respective wind turbines, and using the aero power set points for controlling the respective wind turbines and the storage power set pints for controlling the respective energy storage elements.
In another embodiment, a system for controlling a wind farm including a plurality of wind turbines is provided. The system includes a wind farm controller for computing an error between a farm-level base point power forecast and a measured farm-level active power, generating an aggregated farm-level active power set point for the wind farm based on the error and a frequency response set point, generating aggregated turbine-level active power set points for the respective wind turbines based on the aggregated farm-level active power set point, and transmitting the aggregated turbine-level active power set points to the respective wind turbines. The system also includes wind turbine controllers for receiving the aggregated turbine-level active power set points, using the aggregated turbine-level active power set points for determining aero power set points for respective wind turbines and storage power set points for energy storage elements coupled to the respective wind turbines, and using the aero power set points for controlling the respective wind turbines and the storage power set points for controlling the energy storage elements coupled to the respective wind turbines.
These and other features, aspects, and advantages of the present invention will become better understood when the following detailed description is read with reference to the accompanying drawings in which like characters represent like parts throughout the drawings, wherein:
Unless defined otherwise, technical and scientific terms used herein have the same meaning as is commonly understood by one of ordinary skill in the art to which this disclosure belongs. The terms “first”, “second”, and the like, as used herein do not denote any order, quantity, or importance, but rather are used to distinguish one element from another. Also, the terms “a” and “an” do not denote a limitation of quantity, but rather denote the presence of at least one of the referenced items. The term “or” is meant to be inclusive and mean one, some, or all of the listed items. The use of “including,” “comprising” or “having” and variations thereof herein are meant to encompass the items listed thereafter and equivalents thereof as well as additional items. The terms “connected” and “coupled” are not restricted to physical or mechanical connections or couplings, and can include electrical connections or couplings, whether direct or indirect. Furthermore, the terms “circuit,” “circuitry,” “controller,” and “processor” may include either a single component or a plurality of components, which are either active and/or passive and are connected or otherwise coupled together to provide the described function.
Embodiments of the present invention include a system and method for computing an error between a farm-level base point power forecast and a measured farm-level active power, generating an aggregated farm-level active power set point for the wind farm based on the error and a frequency response set point, generating aggregated turbine-level active power set points for the plurality of wind turbines based on the aggregated farm-level active power set point; transmitting the aggregated turbine-level active power set points to the respective wind turbines, using the aggregated turbine-level active power set points for determining aero power set points for each of the plurality of wind turbines and storage power set points for energy storage elements coupled to each of the respective wind turbines, and using the aero power set points for controlling the respective wind turbines and the storage power set pints for controlling the respective energy storage elements.
In one embodiment, the wind turbine controllers 160 generate the turbine-level base point power forecasts 150 based on aero power forecasts. An aero power forecast for a wind turbine 120 includes a forecast of wind power that may be generated by the wind turbine 120 using wind. In a specific embodiment, the aero power forecast is based on a historical aero power data and real time wind speed. In another embodiment, the wind turbine controller 160 uses a persistence method to determine the aero power forecast. The wind turbine controllers 160 further generate storage power forecasts based on states of charge of the respective energy storage elements 130. In one embodiment, a state of charge signal 170 is sent to the wind turbine controller 160 from a storage management system 180 in each wind turbine 120. The storage power forecast includes a forecast of power that may be provided by the energy storage element 130 of each wind turbine 120 based on the state of charge 170 of the respective energy storage element 130. The storage management system 180 may track the state of charge 170 of the energy storage element 130 based on a droop characteristic curve of the energy storage element 130, for example. In this example, the wind turbine controller 160 generates the storage power forecast based on a position of the state of charge 170 in the droop characteristic curve. In one embodiment, the droop characteristic curve of the energy storage element 130 may be determined based on a type of the energy storage element 130, a size of the wind farm 100, a rating of the energy storage element 130, and variability of the wind.
Referring to
For example,
The wind turbine controller 160 (
Simultaneously, the wind turbine controller generates a second turbine-level base point power forecast represented by reference numeral 420 for the time interval T2 in the corresponding graph 340. The wind turbine controller also obtains the state of charge of the energy storage element at the end of time interval T1. Since the value 410 representing the state of charge is about one (1), the wind turbine controller identifies that the position of the state of charge is in the positive offset slope, and the energy storage element may discharge to provide storage power. Hereinafter, the terms “value representing the state of charge” and “the position of the state of charge” are used interchangeably as the position of the state of charge is represented by the value representing the state of charge. The amount of storage power that may be provided by the energy storage element is computed based on a difference between a target state of charge 430 and a current state of charge represented by the position of the state of charge. Additionally, as the state of charge of the energy storage element is one (1), the energy storage element has reached a saturation condition represented by curve 440. The saturation condition may be defined as a condition in which, the energy storage element has reached a storage power saturation limit and will be unable to further store the differential power that may be received by the energy storage element during the time interval T2. Therefore, the wind turbine controller (
With continued reference to
The wind farm controller 140 computes aggregated turbine-level active power set points 122 for the wind turbines 120 from the aggregated farm-level active power set point by using a distribution logic which may be based on the turbine-level base point power forecasts and respective power rating of the wind turbines. The wind farm controller 140 transmits each aggregated turbine-level active power set point 122 to the respective wind turbine controller 160 of the respective wind turbines 120. The wind turbine controllers 160 use the aggregated turbine-level active power set points 122 to determine aero power set points for the respective wind turbines 120 and storage power set points for the energy storage elements 130 coupled to the respective wind turbines 120.
The wind turbine module 510 includes a first wind summation block 512, a second wind summation block 514, a third wind summation block 516, and a first low pass filter 518. The storage power module 520 includes a second low pass filter 522, a state of charge management system 524 including a droop characteristic curve. The aero module 530 includes a first aero summation block 532, a second aero summation block 534, and a third low pass filter 536. The first low pas filter 518, the second low pass filter 522, and the third low pass filter 536 may be configured to include a first time delay, a second time delay and a third time delay respectively. In one embodiment, the first time delay, the second time delay, and the third time delay are provided such that the first time delay is the lowest, the third time delay is the highest, and the second time delay is between the first time delay and the third time delay which may be represented as TLPF1<TLPF2<TLPF3, where T represents time delay. The first low pass filter 518, the second low pass filter 522, and the third low pass filter 536 enable a sequential operation of the wind turbine module 510, the storage power module 520, and the aero power module 530 to first generate a wind turbine error followed by the storage power set point 550 and the aero power set point 540.
The wind turbine module 510 receives a respective aggregated turbine-level active power set point 560 from the wind farm controller (
Based on the second time delay included in the second low pass filter 522, the state of charge management system 524 in the storage power module 520 determines a state of charge 528 of the energy storage element. The state of charge management system 524 computes a value 610 representative of the storage power that may be provided by the energy storage element based on the state of charge 528 from the droop characteristic curve and transmits the value 610 representative of the storage power to the second wind summation block 514 through the second low pass filter 522 to maintain the second time delay.
The second wind summation block 514 compares the active power difference 600 and the value 610 representative of the storage power to determine if the energy storage element is capable of providing the storage power 610 required to compensate the active power difference 600. The value 610 representative of the storage power is used to generate the storage power set point represented by 550 and is further transmitted to the third wind summation block 516.
The third wind summation block 516 also receives the DC/DC chopper power 580 and computes a difference between the DC/DC chopper power 580 and the value 610 representative of the storage power to determine an active power error 620. The active power error 620 may include an error in active power that may be provided by the wind turbine to the wind farm. The active power error 620 may include an additional power (positive error) that may be received from the wind farm or a deficit in power (negative error) that may be provided to the wind farm for compensating the active power error 600. The second aero summation block 534 receives the aero power 590 from the first aero summation block 532 and the value 620 representative of the active power error. The second aero summation block 534 computes a difference between the aero power 590 and the active power error 620 to determine the aero power set point 540 for the wind turbine to generate aero power.
The method 700 also includes transmitting the aggregated turbine-level active power set points to the respective wind turbines in step 740. The method 700 further includes determining aero power set points and storage power set points for the plurality of wind turbines and the energy storage elements coupled to the plurality of wind turbines respectively by using the aggregated turbine-level active power set points in step 750. In one embodiment, the storage power set points are determined prior to determining the aero power set points. In a specific embodiment, active power differences are determined between the aggregated turbine-level active power set points and aero powers of the wind turbines. In a more specific embodiment, the active power differences are adjusted based on states of charge of the energy storage elements to generate the storage power set points. In another embodiment, the aero power set points are determined by determining an active power error between the storage power set points and a DC/DC chopper power. The method 700 further includes using the aero power set points for controlling the respective wind turbines and the storage power set points for controlling the respective energy storage elements in step 760.
It is to be understood that a skilled artisan will recognize the interchangeability of various features from different embodiments and that the various features described, as well as other known equivalents for each feature, may be mixed and matched by one of ordinary skill in this art to construct additional systems and techniques in accordance with principles of this disclosure. It is, therefore, to be understood that the appended claims are intended to cover all such modifications and changes as fall within the true spirit of the invention.
While only certain features of the invention have been illustrated and described herein, many modifications and changes will occur to those skilled in the art. It is, therefore, to be understood that the appended claims are intended to cover all such modifications and changes as fall within the true spirit of the invention.
Saha, Avijit, Ganireddy, Govardhan, Burra, Rajni Kant, Cardinal, Mark Edward, Sagi, Deepak Raj
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